DE102022205821A1 - Connection arrangement, especially for use in electric vehicles or hybrid vehicles - Google Patents

Abstract

For a connection arrangement (1), in particular for use in electric vehicles or hybrid vehicles, comprising a first flat connection contact (11) with a flat first contact surface (15) for electrically contacting a first electrical and/or electronic component and a second flat connection contact (21) with a second contact surface (25) for electrically contacting a second electrical and/or electronic component, the first flat connection contact (11) and the second flat connection contact (21) overlapping in an overlap region (5), the first contact surface (15) faces the second contact surface (25), the first flat connection contact (11) and the second flat connection contact (21) being connected by means of a connecting element (30) and the first contact surface (15) against the second contact surface through the connecting element (30). (25) is pressed, it is proposed that a structure (17) is embossed into the first flat connection contact (11), so that an edge (16) of the first flat connection contact (11) protrudes from the plane of the first contact surface (15). , wherein the edge (16) protruding from the plane of the first contact surface (15) is pressed by the connecting element (30) into the second contact surface (25) of the second flat connection contact (21).

Description

State of the art

The invention relates to a connection arrangement, in particular for use in electric vehicles or hybrid vehicles, with the features of the preamble of independent claim 1.

In power electronics, for example in electric vehicles or hybrid vehicles, electrical and/or electronic components that carry high electrical currents are connected to one another. Due to the high electrical currents, current-carrying elements through which the electrical and/or electronic components are connected to one another must have correspondingly low electrical resistances and thus have large cross sections and/or materials of high electrical conductivity. In such arrangements, for example, current is conducted via busbars, which are also called busbars, and the electrical and/or electronic components are connected to one another via busbars.

To connect electrical and/or electronic components to one another, flat connection contacts, for example busbars, which form electrical connections of the electrical and/or electronic components, are electrically connected to one another. The flat connection contacts overlap and are connected to one another, for example screwed, in the area in which they overlap. If high currents flow across the connection, maintaining a low electrical material resistance and maintaining a low electrical contact resistance is essential to minimize the overall electrical loss conduction.

Disclosure of the invention

According to the invention, a connection arrangement is proposed, in particular for use in electric vehicles or hybrid vehicles. 1. The connection arrangement comprises a first flat connection contact with a flat first contact surface for electrically contacting a first electrical and/or electronic component and a second flat connection contact with a second contact surface for electrically contacting a second electrical and/or electronic component, the first flat Connection contact and the second flat connection contact overlap in an overlap area, the first contact surface facing the second contact surface, the first flat connection contact and the second flat connection contact being connected by means of a connecting element and the first contact surface being pressed against the second contact surface by the connecting element. According to the invention, a structure is embossed into the first flat connection contact, so that an edge of the first flat connection contact protrudes from the plane of the first contact surface, the edge protruding from the plane of the first contact surface being pressed into the second contact surface of the second flat connection contact by the connecting element .

Advantages of the invention

Compared to the prior art, the connection arrangement with the features of the independent claim has the advantage that an advantageously low electrical contact resistance is achieved in the connection between the two flat connection contacts. This advantageously prevents an otherwise high level of heat development and a high voltage drop at the contact point between the two flat connection contacts. Through the edge of the first flat connection contact, which is pressed into the second contact surface of the second flat connection contact, when the flat connection contacts are mechanically fastened to one another, for example when screwing, the edge is pressed by foreign layers on the second contact surface. The foreign layer can, for example, be an oxide layer caused by corrosion of the second flat connection contact, which would lead to a high contact resistance at the contact point between the two flat connection contacts. When the flat connection contacts are fastened to one another, the edge penetrates the foreign layer on the second contact surface. During the fastening of the flat connection contacts to one another, for example when tightening a screw connection, the embossed structure is pressed flat. This results in a relative movement of the edge on the second contact surface, with the edge being pushed over the second contact surface. This relative movement breaks up the foreign layer on the second contact surface from the edge and at the same time removes the foreign layer on the edge. The relative movement thus breaks up the foreign layers, which can be oxide layers, for example, on the two flat connection contacts. Fastening the flat connection contacts, for example when tightening the screw connection, ensures that areas with an open foreign layer lie on top of each other and that no foreign layer can form in this area on which the areas lie on top of each other. This achieves an advantageously low and stable electrical resistance between the two connection contacts. At the beginning of the screwing process there is line contact between the first flat connection contact and the second flat connection contact. The surface pressure is advantageously high during the screwing process in the area of line contact because the pressed area is very small (surface pressure = force/area). This means that the foreign layer can be broken up very well due to the locally very high force.

Further advantageous refinements and developments of the inventions are made possible by the features specified in the subclaims.

According to an advantageous exemplary embodiment, it is provided that a first recess is formed in the overlap area in the first connection contact, the edge being formed by the edge of the first connection contact around the first recess, the connecting element protruding through the first recess in the first flat connection contact. Thus, the edge around the connecting element is used to create the connection with the lower contact resistance. The recess, for example a hole for receiving a screw, is used at the same time to establish the connection with advantageously low contact resistance using the edge around this recess as an edge. The edge running around the recess for the connecting element can advantageously be pressed all around into the second contact surface and produce an advantageously low electrical contact resistance between the two flat connecting elements. In this case, for example, a head, for example a screw head, of the connecting element can press the edge all around, for example in a ring shape, into the second contact surface of the second flat connecting element when the connecting element is tightened. Due to the annular contact around the first recess, it is possible to establish a connection with advantageously low electrical resistance using small screws.

According to an advantageous exemplary embodiment, it is provided that a funnel-shaped structure embossed around the first recess is formed in the first connection contact. Such a structure is advantageously easy to produce and is particularly suitable for fastening the flat connecting elements to one another, for example when tightening the connecting element designed, for example, as a screw, to cause a good relative movement of the edge on the second contact surface. When tightening, the funnel-shaped structure is flattened and the edge breaks up the foreign layers in the radial direction.

According to an advantageous exemplary embodiment, it is provided that the connecting element is designed as a screw connection and the first flat connection contact and the second flat connection contact are connected to one another and pressed against one another by means of the screw connection. The screw connection creates a particularly simple and at the same time good mechanical connection between the flat connection contacts. Furthermore, by tightening the screw, a force can be exerted on the flat connection contacts, which presses the edge firmly into the second contact surface and sufficient force can be applied to flatten the structure and break up the foreign layer on the second contact surface and the edge. A screw head can, for example, press all around the first recess onto the funnel-shaped structure, for example, and thus press the edge all around the first recess into the second contact surface. The edge is pushed radially away from the connecting element over the second contact surface and thus breaks up the foreign layer on the second contact surface in a ring.

According to an advantageous exemplary embodiment, it is provided that a second recess is formed in the second flat connection contact, through which the connecting element protrudes, the edge around the first recess, in particular in a ring shape, the second recess being pressed all around into the second contact surface. The connecting element can thus be arranged through both recesses and the two flat connection contacts can be connected to one another in a simple manner.

According to an advantageous exemplary embodiment, it is provided that the first flat connection contact is designed as a busbar and/or the second flat connection contact is designed as a busbar. The busbars can be connected to one another particularly well in the manner shown; in particular, the busbars can advantageously be simply and inexpensively punched and embossed. The first recess in a busbar can advantageously be easily manufactured by punching. A punched recess then has, for example, a particularly sharp edge, which can advantageously easily break through the foreign layer on the second contact surface. The embossed structure can be produced particularly easily on a first flat connection contact designed as a busbar.

Furthermore, a method for producing a connection arrangement is proposed. The method includes a step for providing a first flat connection contact, in particular special a busbar, with a flat first contact surface, a step for providing a second flat connection contact with a second contact surface, a step for embossing a structure into the first flat connection contact, an edge of the first flat connection contact being embossed out of the plane by embossing the structure the flat first contact surface is pressed out, a step for arranging the first contact surface of the first flat connection contact on the second contact surface of the second flat connection contact, a step for attaching the first flat connection contact to the second flat connection contact by means of a connecting element, wherein the first contact surface of the first flat connection contact is pressed against the second contact surface of the second flat connection contact and the edge of the first flat connection contact is pressed into the second contact surface of the second flat connection contact. In this way, a connection arrangement with advantageously low electrical contact resistance between the flat connection contacts can be produced in a simple and cost-effective manner. The foreign layers on the two flat connection contacts are broken up at the contact points and a stable contact with low electrical contact resistance is created between the two flat connection contacts.

According to an advantageous exemplary embodiment, it is provided that a first recess is formed in the first flat connection contact, the edge of the first flat connection contact forming the edge around the first recess, wherein when the first flat connection contact is fastened to the second flat connection contact, the connecting element, in particular a screw connection through which the first recess is inserted. In this way, a mechanically stable connection with low electrical contact resistance can be created in a simple manner.

According to an advantageous exemplary embodiment, it is provided that a funnel-shaped structure is embossed around the first recess, the edge being pressed out of the plane of the first contact surface in a ring shape. Such a structure is particularly suitable when a screw head presses the first flat connection contact against the second flat connection contact. The structure is flattened evenly when the connection is tightened and the edge moves in the radial direction away from the connecting element, for example designed as a screw, over the second contact surface and breaks up the foreign layer on the second contact surface in a ring shape around the connecting element.

According to an advantageous exemplary embodiment, it is provided that when the first flat connection contact is fastened to the second flat connection contact, the edge is pressed in a ring shape, in particular surrounding a second recess in the second flat connection contact, into the second contact surface of the second flat connection contact. This creates an advantageously good contact with low electrical contact resistance.

Brief description of the drawings

• 1 ein Ausführungsbeispiel eines ersten flächigen Anschlusskontakts,
• 2 eine weitere Ansicht des Ausführungsbeispiels des ersten flächigen Anschlusskontakts,
• 3 einen Querschnitt durch das Ausführungsbeispiel des ersten flächigen Anschlusskontakts,
• 4 einen Querschnitt durch ein Ausführungsbeispiel der Verbindungsanordnung vor dem Befestigen des ersten flächigen Anschlusskontakts an dem zweiten flächigen Anschlusskontakt,
• 5 einen vergrößerten Querschnitt durch das Ausführungsbeispiel der Verbindungsanordnung beim Befestigen des ersten flächigen Anschlusskontakts an dem zweiten flächigen Anschlusskontakt,
• 6 einen Querschnitt durch ein Ausführungsbeispiel der Verbindungsanordnung nach dem Befestigen des ersten flächigen Anschlusskontakts an dem zweiten flächigen Anschlusskontakt.

An exemplary embodiment of the invention is shown in the drawing and is explained in more detail in the following description. Show it

• 1 an embodiment of a first flat connection contact,
• 2 a further view of the exemplary embodiment of the first flat connection contact,
• 3 a cross section through the exemplary embodiment of the first flat connection contact,
• 4 a cross section through an exemplary embodiment of the connection arrangement before attaching the first flat connection contact to the second flat connection contact,
• 5 an enlarged cross section through the exemplary embodiment of the connection arrangement when attaching the first flat connection contact to the second flat connection contact,
• 6 a cross section through an exemplary embodiment of the connection arrangement after attaching the first flat connection contact to the second flat connection contact.

Embodiments of the invention

1 until 3 show different views of an exemplary embodiment of a first flat connection contact 11. 4 until 5 show an exemplary embodiment of the connection arrangement 1 with the exemplary embodiment of the first flat connection contact 11 1 until 3 . The connection arrangement 1 can be used in all applications in which high currents must be conducted via contact connections and power losses must be kept low. The connection arrangement 1 can be used, for example, in systems that carry high currents, for example in power electronics, for example in electric vehicles witnesses or hybrid vehicles can be used. For example, the connection arrangement 1 can be used in power electronics, in converters or batteries.

The connection arrangement 1 comprises a first flat connection contact 11, which can be, for example, an electrical connection of a first electrical and/or electronic component. Furthermore, the connection arrangement 1 comprises a second flat connection contact 21, which can be, for example, an electrical connection of a second electrical and/or electronic component. The electrical and/or electronic components can be or include, for example, inverters, converters, DC/DC converters, capacitors, such as intermediate circuit capacitors, batteries or, for example, other electronic and/or electrical components that are used in electric vehicles or hybrid vehicles.

The first electrical and/or electronic component is electrically conductively connected to the second electrical and/or electronic component. The electrically conductive connection between the first electrical and/or electronic component and the second electrical and/or electronic component is established via the flat connection contacts 11, 21. For this purpose, the first flat connection contact 11 is connected to the second flat connection contact 21 in an electrically conductive manner. For this purpose, the first flat connection contact 11 lies flat, in particular directly, on the second flat connection contact 21.

The flat connection contacts 11, 21 are made of an electrically conductive material, for example a metal, for example copper. Copper has an advantageously low material resistance. The first flat connection contact 11 can be made of the same material as the second flat connection contact 21. The first flat connection contact 11 and the second flat connection contact 21 can also be made of different materials. The flat connection contacts 11, 21 are essentially flat, at least in the area in which they overlap. The flat connection contacts 11, 21 have flat contact surfaces 12, 22 in the overlap area 5, on which the flat connection contacts 11, 21 rest against one another, so that an electrically conductive connection between the flat connection contacts 11, 21 is established. The flat connection contacts 11, 21 are arranged plane-parallel to one another with respect to their flat extension planes. In the exemplary embodiment shown, the flat connection contacts 11, 21 are designed as busbars 11, 21. In the context of the present application, a busbar 11, 21 is understood to mean an electrically conductive flat conductor, for example an electrically conductive strip or an electrically conductive strip. A bus bar can therefore be a bus bar, for example. The busbars 11, 21 can, for example, be bent or curved or can also run like a curve or step. The busbars 11, 21 are made of an electrically conductive material, for example a metal such as copper. The busbars 11, 21 are, for example, formed in one piece. The busbars 11, 21 are, for example, continuously made of the same material. The busbars 11, 21 are designed, for example, as stamped parts. For example, each of the busbars 11, 21 has a constant thickness of the busbar 11, 21 over a longitudinal extent of the busbars 11, 21, for example perpendicular to the current direction. For example, each of the busbars 11, 21 can have a width of the busbar 11, 21 that is constant over a longitudinal extent of the busbars 11, 21, for example perpendicular to the current direction. A first recess 12 is formed in the first flat connection contact 11. A second recess 22 is formed in the second flat connection contact 21. The first recess 12 in the first flat connection contact 11 has, for example, a larger surface area than the second recess 22 in the second flat connection contact 21.

The recesses 12, 22 serve to accommodate a connecting element 30 for mechanically connecting the flat connection contacts 11, 21 to one another. The connecting element 30 is inserted through the recesses 12, 22. The connecting element 30 is tightened and thus presses the contact surfaces 12, 22 of the flat connection contacts 11, 21 against each other. The connecting element 30 establishes a mechanical connection between the first flat connection contact 11 and the second flat connection contact 21. The connecting element 30 can be designed as a screw 31, for example. The screw 31 is passed through the connection contacts 11, 21 in the overlap area 5, in which the connection contacts 11, 21 overlap. For this purpose, a first recess 12 is formed in the first flat connection contact 11 and a second recess 22 is formed in the second flat connection contact 21. The screw 31 projects through the first recess 12 of the first flat connection contact 11 and through the second recess 22 of the second flat connection contact 21. The screw 31 is spaced in the recesses 12, 22 from the first flat connection contact 11 and from the second flat connection contact 21 and does not touch them. At a first end of the screw 31 there is a Screw head 32 is formed. At the second end of the screw 31 facing away from the first end of the screw 31, the screw 31 is screwed into a counter thread 33. The counter thread 33 is formed in another component 35, for example a screw bushing, a screw nut or a housing. The screw head 32 covers the first recess 12 in the first flat connection contact 11 and thus acts on the first flat connection contact 11 when the screw 31 is screwed into the mating thread 33, which forces the first contact surface 15 of the first flat connection contact 11 against the second contact surface 25 of the second flat connection contact 21 presses. The screw head 32, for example, has a larger diameter than the first recess 12. The screw 31 thus presses the first contact surface 15 of the first flat connection contact 11 onto the contact surface 25 of the second flat connection contact 21. The two flat connection contacts 11, 21 are arranged between the screw head and the mating thread 33. The connecting element 30 can be made of a metal, for example steel.

In 1 until 3 an exemplary embodiment of the first flat connection contact 11 is shown. The first flat connection contact 11 in this exemplary embodiment is designed as a bus bar, also called a bus bar. The first flat connection contact 11 is made of an electrically conductive material, for example a metal, for example copper. The first electrical connection contact 11 is, for example, punched and/or bent and/or embossed from a sheet metal. The first flat connection contact 11 has a first contact surface 15. The first contact surface 15 is flat and therefore extends in one plane. A first recess 12 for receiving a connecting element 30 is formed in the first connection contact 11. In this exemplary embodiment, the first recess 12 is punched in the first connection contact 11. The first recess 12 can, for example, be a hole for receiving a screw as a connecting element 30. Furthermore, a structure 17 is embossed into the first connection contact 11 around the first recess 12. The structure 17 is funnel-shaped. Due to the funnel-shaped structure 17, the edge of the first connection contact 11 is bent out of the plane of the first contact surface 15 around the first recess 12 and protrudes from it. This forms an edge 16 which presses into the second contact surface 22 when fastening, in particular when screwing, the first flat connection contact 11 with the second flat connection contact 21.

In the 4 until 6 shows how the electrically conductive and mechanical connection between the flat connection contacts 11, 21 of the connection arrangement 1 is established. 4 shows a cross section through an exemplary embodiment of the connection arrangement 1 before attaching the first flat connection contact 11 to the second flat connection contact 21.

5 shows an enlarged cross section through the exemplary embodiment of the connection arrangement 1 when attaching the first flat connection contact 11 to the second flat connection contact 21. When the screw 31 is tightened, the edge 16 of the first flat connection contact 11 rests pointedly on the second contact surface 25 of the second flat connection contact 21 . The edge 16 points in the direction of the second contact surface 25. If the screw 31 is tightened further, the structure 17 embossed into the first flat connection contact 11 is pressed flat and the edge 17 breaks through the foreign layer, for example the oxide layer, on the second contact surface 25. The Arrow shows the direction of movement of the edge 17 on the second contact surface 25 when the screw is tightened and the structure 17 is flattened.

6 shows a cross section through the exemplary embodiment of the connection arrangement 1 after fastening the first flat connection contact 11 to the second flat connection contact 21. After tightening the screw, the relative movement of the edge 17 on the second contact surface 25 causes the foreign layers, which can be oxide layers, for example, broken open on the two flat connection contacts 11, 21 in the area of the edge 16. The edge 16 is pressed into the second contact surface 25.

The structure 17 is largely or completely flattened by the force of the screw connection, particularly in the area under the screw head 32.

Of course, further exemplary embodiments and hybrid forms of the exemplary embodiments shown are also possible.

Claims (10)

Connection arrangement (1), in particular for use in electric vehicles or hybrid vehicles, comprising a first flat connection contact (11) with a flat first contact surface (15) for electrically contacting a first electrical and/or electronic component and a second flat connection contact (21) with a second contact surface (25) for electrical contacting of a second electrical and/or electronic component, wherein the first flat connection contact (11) and the second flat connection contact (21) overlap in an overlap region (5), the first contact surface (15) facing the second contact surface (25), the first flat connection contact (11 ) and the second flat connection contact (21) are connected by means of a connecting element (30) and the first contact surface (15) is pressed against the second contact surface (25) by the connecting element (30), characterized in that in the first flat connection contact ( 11) a structure (17) is embossed so that an edge (16) of the first flat connection contact (11) protrudes from the plane of the first contact surface (15), the edge (16.) protruding from the plane of the first contact surface (15). ) is pressed by the connecting element (30) into the second contact surface (25) of the second flat connection contact (21). Connection arrangement according to Claim 1 , characterized in that a first recess (12) is formed in the first connection contact (11) in the overlap area (5), the edge (16) being formed by the edge of the first connection contact (11) around the first recess (12). , wherein the connecting element (30) protrudes through the first recess (12) in the first flat connection contact (11). Connection arrangement according to one of the preceding claims, characterized in that a funnel-shaped structure (17) embossed around the first recess (12) is formed in the first connection contact (11). Connection arrangement according to one of the preceding claims, characterized in that the connecting element (30) is designed as a screw (31) and the first flat connection contact (11) and the second flat connection contact (21) are connected to one another and pressed against one another by means of the screw (31). . Connection arrangement according to one of the Claims 2 until 4 , characterized in that a second recess (22) is formed in the second flat connection contact (21), through which the connecting element (30) projects, the edge (16) around the first recess (12), in particular annular, forming the second Recess (22) is pressed circumferentially into the second contact surface (25). Connection arrangement according to one of the preceding claims, characterized in that the first flat connection contact (11) is designed as a busbar and/or the second flat connection contact (21) is designed as a busbar. Method for producing a connection arrangement, comprising the steps: - Providing a first flat connection contact (11), in particular a busbar, with a flat first contact surface (15), - Providing a second flat connection contact (21) with a second contact surface (25), - Embossing a structure (17) into the first flat connection contact (11), an edge (16) of the first flat connection contact (11) being pressed out of the plane of the flat first contact surface (15) by embossing the structure (17), - Arranging the first contact surface (15) of the first flat connection contact (11) on the second contact surface (25) of the second flat connection contact (21) - Fastening the first flat connection contact (11) to the second flat connection contact (21) by means of a connecting element (30), the first contact surface (15) of the first flat connection contact (11) being against the second contact surface (25) of the second flat connection contact ( 21) is pressed and the edge (16) of the first flat connection contact (11) is pressed into the second contact surface (25) of the second flat connection contact (21). Procedure according to Claim 7 , characterized in that a first recess (12) is formed in the first flat connection contact (11), the edge of the first flat connection contact (11) forming the edge (16) around the first recess (12), whereby when fastening the first flat connection contact (11) on the second flat connection contact (21) of the connecting element (30), in particular a screw (31), is inserted through the first recess (12). Procedure according to Claim 8 , characterized in that a funnel-shaped structure (17) is embossed around the first recess (12), the edge (16) being pressed out of the plane of the first contact surface (15) in a ring shape. Procedure according to Claim 8 or 9 , characterized in that when attaching the first flat connection contact (11) to the second flat connection contact (21), the edge (16) is annular, in particular a second recess (22) in the second flat connection contact (21), in the second contact surface (25) of the second flat connection contact (21) is pressed.

Images